#' The Poisson Distribution
#'
#' \lifecycle{stable}
#'
#' Poisson distributions are frequently used to model counts.
#'
#' @inheritParams stats::dpois
#'
#'
#' @details
#'
#'   We recommend reading this documentation on
#'   <https://pkg.mitchelloharawild.com/distributional/>, where the math
#'   will render nicely.
#'
#'   In the following, let \eqn{X} be a Poisson random variable with parameter
#'   `lambda` = \eqn{\lambda}.
#'
#'   **Support**: \eqn{\{0, 1, 2, 3, ...\}}{{0, 1, 2, 3, ...}}
#'
#'   **Mean**: \eqn{\lambda}
#'
#'   **Variance**: \eqn{\lambda}
#'
#'   **Probability mass function (p.m.f)**:
#'
#'   \deqn{
#'     P(X = k) = \frac{\lambda^k e^{-\lambda}}{k!}
#'   }{
#'     P(X = k) = \lambda^k e^(-\lambda) / k!
#'   }
#'
#'   **Cumulative distribution function (c.d.f)**:
#'
#'   \deqn{
#'     P(X \le k) = e^{-\lambda}
#'     \sum_{i = 0}^{\lfloor k \rfloor} \frac{\lambda^i}{i!}
#'   }{
#'     P(X \le k) = e^(-\lambda)
#'     \sum_{i = 0}^k \lambda^i / i!
#'   }
#'
#'   **Moment generating function (m.g.f)**:
#'
#'   \deqn{
#'     E(e^{tX}) = e^{\lambda (e^t - 1)}
#'   }{
#'     E(e^(tX)) = e^(\lambda (e^t - 1))
#'   }
#' @seealso [stats::Poisson]
#'
#' @examples
#' dist <- dist_poisson(lambda = c(1, 4, 10))
#'
#' dist
#' mean(dist)
#' variance(dist)
#' skewness(dist)
#' kurtosis(dist)
#'
#' generate(dist, 10)
#'
#' density(dist, 2)
#' density(dist, 2, log = TRUE)
#'
#' cdf(dist, 4)
#'
#' quantile(dist, 0.7)
#'
#' @name dist_poisson
#' @export
dist_poisson <- function(lambda){
  lambda <- vec_cast(lambda, double())
  if(any(lambda < 0)){
    abort("The lambda parameter of an Poisson distribution must be non-negative.")
  }
  new_dist(l = lambda, class = "dist_poisson")
}

#' @export
format.dist_poisson <- function(x, digits = 2, ...){
  sprintf(
    "Pois(%s)",
    format(x[["l"]], digits = digits, ...)
  )
}

#' @export
density.dist_poisson <- function(x, at, ...){
  stats::dpois(at, x[["l"]])
}

#' @export
log_density.dist_poisson <- function(x, at, ...){
  stats::dpois(at, x[["l"]], log = TRUE)
}

#' @export
quantile.dist_poisson <- function(x, p, ...){
  stats::qpois(p, x[["l"]])
}

#' @export
cdf.dist_poisson <- function(x, q, ...){
  stats::ppois(q, x[["l"]])
}

#' @export
generate.dist_poisson <- function(x, times, ...){
  stats::rpois(times, x[["l"]])
}

#' @export
mean.dist_poisson <- function(x, ...){
  x[["l"]]
}

#' @export
covariance.dist_poisson <- function(x, ...){
  x[["l"]]
}

#' @export
skewness.dist_poisson <- function(x, ...) 1 / sqrt(x[["l"]])

#' @export
kurtosis.dist_poisson <- function(x, ...) 1 / x[["l"]]
